System and method for the construction of interactive virtual objects

ABSTRACT

The present disclosure relates to a system and method for constructing an interactive virtual object in a virtual environment implemented in a computer, wherein the computer comprises one or more input devices and one or more output devices providing a user interface allowing a user to interact with the virtual environment, wherein the virtual environment comprises a first virtual construction element carrying a first interactive behavior and a second virtual construction element not carrying the first interactive behavior, wherein the first and second virtual construction elements are connectable to each other by means of a coupling mechanism to form a combined virtual object, and wherein the first virtual construction element imparts the first interactive behavior to the combined virtual object when the first and second construction elements are connected to each other.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation of U.S. patent applicationSer. No. 17/229,318, filed Apr. 13, 2021 and published on Oct. 13, 2022as U.S. Patent Publication No. 2022/0323865 A1, the entirety of which isincorporated herein by reference for any purpose whatsoever.

FIELD OF THE DISCLOSURE

The disclosure relates in one aspect to a system for constructing aninteractive virtual object from other virtual objects, such asconstructing an interactive virtual toy construction model from virtualtoy construction elements. In a particular aspect, the disclosureprovides an improvement over known systems for constructing virtual toyconstruction models by facilitating the construction of interactivevirtual toy construction models. In a further particular aspect, thedisclosure relates to a video game system for the construction of andinteraction with virtual objects in a virtual world environment. In afurther aspect, the disclosure relates to a game creation system for thecreation of video games involving the construction and interaction withvirtual objects in a virtual world environment. In a yet further aspect,the disclosure relates to a method of constructing interactive virtualobjects in a virtual world environment.

BACKGROUND OF THE DISCLOSURE

Modular toy systems and, in particular, modular toy construction systemshave been known for decades. In particular, toy construction systemscomprising toy construction elements having coupling members fordetachably interconnecting construction elements with each other inorder to build toy construction models have gained high popularity. Wellknown toy construction systems include, for example, brick-shapedbuilding blocks with coupling members of the stud and cavity typeproviding a reliable friction engagement coupling for building toyconstruction models at all levels of complexity, thereby allowing for anengaging play experience that can be adapted to suit all ages of users.Modular toy construction systems are often valued for their high levelof flexibility facilitating a creative play experience—both whenconstructing toy construction models and when playing with the finishedmodels.

There is a general desire to bring the highly flexible and engaging playexperience facilitated by physical toy construction systems into thevirtual world. In this regard, programs are being developed that enableusers to virtually construct models from virtual construction elements,for example in order to easily inspect models prior to physical modelbuilding, to minimize trials and errors in model building, or to be ableto easily create and share toy construction sets with instructions forbuilding physical toy construction models. However, it is stilldesirable to enhance the educational and play value of virtual toysystems. For example, it is desirable to enhance the interactive natureof the constructed models in order to enhance the play experience of thevirtual toy construction systems. It is further desirable to provide avirtual toy system that stimulates a creative building and playexperience that is suitable for children without a detailedunderstanding of programming techniques, control systems, or the like.Yet further, it is desirable to provide an interactive play experiencethat can be configured and re-configured by the user to allow for avariety of different interactive play experiences. In particular, it isdesirable to facilitate an easy way of creating, configuring, andre-configuring an interactive play experience.

Therefore there is still a need for new and/or improved systems for thecreation of interactive virtual objects.

SUMMARY OF THE DISCLOSURE

In one aspect a system for constructing an interactive virtual model isprovided, the system comprising a processing unit, one or more outputdevices, and one or more input devices, wherein the processing unit isoperatively coupled to the input and output devices so as to provide auser interface to a user of the system. The processing unit may comprisea processor device and memory means, the memory means comprisingprogrammed instructions, which when executed by the processor devicecause the system to produce an interactive virtual environmentconfigured to allow the user to interact with the virtual environmentthrough the user interface. The virtual environment may comprise aplurality of virtual construction elements, wherein the virtualconstruction elements are connectable to each other so as to construct avirtual model. A first one of the virtual construction elements carriesa first interactive behavior, wherein the first virtual constructionelement is configured to receive a stimulus and to generate a responseresponsive to receiving said stimulus according to a first responsefunction, a second one of the virtual construction elements does notcarry the first interactive behavior, and the first virtual constructionelement is configured, or at least configurable, to impart the firstinteractive behavior to the second virtual construction element when thefirst and second construction elements are connected to each other.

In a further aspect, a system for constructing an interactive virtualobject in a virtual environment implemented in a computer is provided,the computer comprising one or more input devices and one or more outputdevices allowing a user to interact with the virtual environment. Thevirtual environment may comprise a first virtual construction elementcarrying a first interactive behavior, and a second virtual constructionelement not carrying the first interactive behavior, wherein the firstand second virtual construction elements are connectable to each otherby means of a coupling mechanism to form a combined virtual object, andwherein the first virtual construction element imparts the firstinteractive behavior to the combined virtual object when the first andsecond construction elements are connected to each other.

Virtual construction elements may be directly or indirectly connected toeach other. Virtual construction elements are considered as directlyconnected to each other when a coupling mechanism is directly engagedbetween the connected virtual construction elements, e.g. by means ofcooperating coupling members arranged on the virtual constructionelements that are engaged to each other so as to couple the virtualconstruction elements together. Direct connection typically requiresthat the directly connected first and second virtual objects aredirectly adjacent to each other.

Indirect connection does not require that the first and second virtualobjects are directly adjacent to each other, i.e. they may or may not bedirectly adjacent to each other. However, coupling members of indirectlyconnected elements are not directly engaged with each other. Instead,indirectly connected elements are connected to each other viaintermediate directly connected elements, i.e. through an uninterruptedpath of direct connections.

The term interactive behavior as used herein is understood as thefunctionality of a virtual object that causes generation of an outputsignal responsive to an input signal received by the virtual object,wherein the input signal may be referred to as ‘stimulus’, and theoutput signal may be referred to as ‘response’. The response isdetermined by a response function on the basis of the received stimulus.A virtual object carrying an interactive behavior is thus configured toreceive a stimulus at a stimulus input, and to generate a response at aresponse output, responsive to receiving said stimulus.

An interactive virtual object may be an interactive virtual toyconstruction element or an interactive virtual toy construction modelconstructed from virtual toy construction elements. Using embodiments ofthe disclosure, a virtual toy construction element or model notexhibiting any interactive behavior may be converted into an interactivevirtual toy construction model by connecting an interactive virtual toyconstruction element to the model, and thus imparting the interactivebehavior as defined and configured by the interactive virtual toyconstruction element to the resulting model. Furthermore, usingembodiments of the disclosure the interactive behavior of an interactivevirtual toy construction model may be modified by adding, removing, orreplacing interactive virtual toy construction elements in the model.Furthermore, the interactive behavior of the interactive virtual toyconstruction elements in an interactive virtual toy construction modelmay be configurable. Thereby, the interactive behavior of the virtualtoy construction model comprising configurable interactive toyconstruction elements may be modified accordingly.

In some embodiments, the second one of the virtual construction elementscarries a second interactive behavior, wherein the second virtualconstruction element is configured to receive a stimulus and to generatea response responsive to receiving said stimulus according to a secondresponse function. In some embodiments, the stimulus input of a firstinteractive virtual toy construction element may be configurable toreceive a stimulus from the response output of another interactivevirtual toy construction element, so as to stimulate the response of thefirst interactive virtual toy construction element, via the response ofthe second virtual interactive toy construction element, by stimulatingthe second virtual interactive toy construction element. The secondresponse output of the second interactive toy construction element maythus be linked to the first stimulus input of the first interactive toyconstruction element. Thereby, a new interactive virtual behavior may beconstructed from two or more interactive virtual toy constructionelements that are linked to each other.

According to some embodiments, a link between two or more interactivevirtual toy construction elements may be configured to be determinedaccording to direct and/or indirect connectivity. For example, aresponse output may be configured to affect the stimulus input of alldirectly and indirectly connected interactive virtual toy constructionelements, only directly connected interactive virtual toy constructionelements, only indirectly connected interactive virtual toy constructionelements, and/or selected ones of the directly and indirectly connectedinteractive virtual toy construction elements. Furthermore, a stimulusinput of one interactive virtual construction element may be linked tothe response output of all directly and indirectly connected interactivevirtual toy construction elements, only directly connected interactivevirtual toy construction elements, only indirectly connected interactivevirtual toy construction elements, and/or selected ones of the directlyand indirectly connected interactive virtual toy construction elements.Thereby, a new interactive behavior of the virtual toy constructionmodel comprising the linked interactive toy construction elements may beconstructed accordingly.

According to some embodiments, a link between two or more virtual toyconstruction elements may be configured independent of connectivity. Forexample, the stimulus input of a first interactive virtual toyconstruction element may be linked to the response output of a secondinteractive virtual toy construction element in a second interactivevirtual toy construction model separate from the first interactivevirtual toy construction model. The interactive behavior of the firstand second interactive virtual toy construction models may thus belinked to each other. More generally, a new interactive virtual behaviormay thus be constructed from two or more interactive virtual toyconstruction models that are linked to each other. Thereby aninteractive virtual world with interactive virtual objects having alinked interactive behavior may be built in an easily accessible andintuitive manner. This is particularly useful for the creation of gamesin the virtual environment, with challenging interactive tasks for aplayer to solve.

Advantageously, interactive steps of constructing, configuring, and/orlinking the interactive behaviors of elements and models in the virtualenvironment may be performed by a user of the system, e.g. in a buildingoperational mode. Thereby, the user may modify the interactiveexperience of a player when the player is playing with the elements andmodels in the virtual environment, e.g. in a playing operational mode.In some embodiments, interactive virtual toy construction elementsand/or models may be provided by the system with a pre-configuredinteractive behavior. Thereby providing a low barrier entrance to usingthe system and improving the user experience for unexperienced users,such as younger children. According to some embodiments, the secondvirtual construction element may also impart the second interactivebehavior to the first virtual construction element when the first andsecond construction elements are connected to each other, in particularwhen the second interactive behavior is different from the firstinteractive behavior.

Advantageously, each of the virtual construction elements comprises oneor more coupling members for connecting two or more virtual constructionelements to each other. Thereby, a coupling mechanism is defined forconnecting said virtual construction element to one or more cooperatingvirtual construction elements, so as to construct a virtual constructionmodel. A virtual construction model may be defined as a group ofconnected virtual construction elements and information defining therelative positions and connectivity of the virtual construction elementsin the group with respect to each other.

The virtual environment may provide a plurality of virtual constructionelements, which comprises a set of passive virtual construction elementsadapted for virtual model building, the passive virtual constructionelements not carrying an interactive behavior. The virtual environmentmay further provide a plurality of virtual construction elements, whichcomprises a set of interactive virtual construction elements adapted forvirtual model building, each of the interactive virtual constructionelements carrying a respective interactive behavior. The interactivevirtual construction elements may comprise action elements, each actionelement carrying a respective action behavior configured to produce auser-perceptible output at the user interface in response to a stimulusreceived at the stimulus input of the action element. The interactivevirtual construction elements may further comprise trigger elements,each trigger element carrying a respective trigger behavior configuredto produce a trigger event or state at the response output of thetrigger element in response to a stimulus received at the stimulus inputof the trigger element.

In a yet further aspect, a method for constructing an interactivevirtual object in a virtual environment is provided. The virtualenvironment may be implemented in a computer arrangement, the computerarrangement being adapted to provide a user interface allowing a user tointeract with the virtual environment. The method may comprise steps of:

-   -   providing a first virtual object carrying a first interactive        behavior, wherein the first virtual object is configured to        receive a stimulus and to generate a response responsive to        receiving said stimulus according to a first response function;    -   providing a second virtual object not carrying the first        interactive behavior,    -   connecting the first and second objects to each other by means        of a coupling mechanism to form a combined virtual object; and    -   imparting the interactive behavior of the first virtual object        to the combined virtual object when the first and second virtual        objects are connected to each other.

In some embodiments, the first virtual object may be one of aninteractive virtual construction element and an interactive virtualconstruction model constructed from a plurality of virtual constructionelements including at least one interactive virtual constructionelement. In some embodiments, the second virtual object may be a virtualconstruction model constructed from a plurality of virtual constructionelements. In some embodiments, the method may further comprise steps of:

-   -   configuring the first virtual object to modify the first        interactive behavior; and    -   imparting the modified first interactive behavior to the        combined virtual object.

Furthermore, the second virtual object may carry a second interactivebehavior, wherein the second virtual object is configured to receive astimulus and to generate a response responsive to receiving saidstimulus according to a second response function. The method may thenfurther comprise steps of linking a response output of the secondvirtual object as a stimulus to a stimulus input of the first virtualobject. Advantageously, steps of constructing, configuring, and/orlinking the interactive behaviors of elements and models in the virtualenvironment may be performed by a user of the system, e.g. in a buildingoperational mode. Thereby, the user may modify the interactiveexperience of a player playing with the elements and models in thevirtual environment, e.g. in a playing operational mode.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-3 each show a prior art toy construction element.

FIG. 4 shows a prior art system for building virtual toy constructionmodels.

FIG. 5 shows an embodiment of a system for building interactive virtualtoy construction models.

FIG. 6 shows behavior toy construction elements of a system for buildinginteractive virtual toy construction models, such as the system of FIG.5 , each behavior toy construction element representing a specificaction associated therewith.

FIG. 7 shows behavior toy construction elements of a system for buildinginteractive virtual toy construction models, such as the system of FIG.5 , each behavior toy construction element representing a specifictrigger associated therewith.

FIG. 8 shows an example of building an interactive toy constructionmodel using a system for building interactive virtual toy constructionmodels, such as the system of FIG. 5 , in a building mode.

FIG. 9 shows an example of playing with an interactive toy constructionmodel using a system for building interactive virtual toy constructionmodels, such as the system of FIG. 5 , in a playing mode.

FIGS. 10-12 show an example of modifying an interaction behavior of avirtual toy construction model, wherein FIGS. 10 and 12 show thebehavior of the virtual toy construction model when the system is in aplaying mode before and after the modification, respectively, andwherein FIG. 11 shows applying the modification to the virtual toyconstruction model when the system is in a building mode.

DETAILED DESCRIPTION

Various aspects and embodiments of toy construction systems disclosedherein will now be described with reference to toy construction elementsin the form of bricks. However, the disclosure may be applied to otherforms of modular construction elements for use in toy construction sets.

FIG. 1 shows a modular toy construction element with coupling pegs, alsocalled studs, on its top surface and a cavity extending into the brickfrom the bottom. The cavity has a central tube, and coupling pegs onanother brick can be received in the cavity in a frictional engagementas disclosed in U.S. Pat. No. 3,005,282. FIGS. 2 and 3 show other suchprior art construction elements. The construction elements shown in theremaining figures have this known type of coupling members in the formof cooperating pegs and cavities. However, other types of couplingmembers may also be used in addition to or instead of the pegs andcavities. The coupling pegs are arranged in a square planar grid, i.e.defining orthogonal directions along which sequences of coupling pegsare arranged. The distance between neighboring coupling pegs is uniformand equal in both directions. This or similar arrangements of couplingmembers at coupling locations defining a regular planar grid allow thetoy construction elements to be interconnected in a discrete number ofpositions and orientations relative to each other, in particular atright angles with respect to each other. The toy construction elementsshown here, in FIGS. 1-3 , are of the passive type, without additionalfunctionality beyond mechanical model building.

Such toy construction elements can also be implemented in a computer asvirtual toy construction elements for virtual model building, therebyproviding a virtual toy construction system, wherein each virtualconstruction element has a shape as defined by circumferential surfaces,and wherein each virtual construction element further has one or morecoupling members configured to allow coupling connections betweencooperating virtual construction elements. The virtual toy constructionelements are configured to have the same modularity and couplingproperties as the corresponding physical toy construction elements.Thereby, a virtual model building system may be provided, whichcorresponds to physical model building with a physical toy constructionsystem, and allows for virtual model building, wherein each virtual toyconstruction model is defined by a set of virtual toy constructionelements and information defining their positioning and connectivitywith respect to each other.

FIG. 4 shows a prior art virtual toy construction system for virtualmodel building using virtual toy construction elements. The systemincludes a processing unit 1, a display unit 2, and input devices 3. Theprocessing unit 1 may comprise, besides a processor, volatile andnon-volatile memory, and may further have access to networked resources,such as cloud storage and computing. The processing unit comprisesand/or has networked access to programmed instructions, which provide,when executed by the processor, a virtual building environment 4. Thevirtual building environment may include a command interface 5, agraphics interface 6, a parts library 7, and a configuration interface8. The parts library 7 may comprise all the virtual toy constructionelements 9 available in the virtual building environment 4, or at leastsub-sets thereof, e.g. in the form of a palette as seen in FIG. 4 .Using one or more of the input devices 3, a user of the virtual toyconstruction system may select from the available virtual toyconstruction elements, position the selected toy construction elementswith respect to each other in a coordinate system of the virtualbuilding environment, and instruct the system to connect the selectedtoy construction elements to each other in order to build a virtual toyconstruction model 10. The toy construction model may be visualized inthe graphics interface 6, e.g. as an elevational view. The configurationinterface 8 may provide configuration information related to thebuilding process. In particular, the configuration interface may providetextual information on the virtual toy construction model, such as adata structure 11 defining the model 10. The data structure may comprisea complete list of the virtual toy construction elements included in themodel 10 and their connectivity.

FIG. 5 shows a system 100 for constructing interactive virtual objectsaccording to one embodiment of the disclosure. The system 100 has aprocessing unit 101 comprising a processor device and memory means,output devices 102, such as a display, and input devices 103, such as atouch panel or any suitable other input device. The processing unit 101is configured to control the display 102 and receive user input from theinput device 103. The processing unit 101 further comprises, or hasaccess to, programmed instructions, which when executed by a processordevice of the processing unit causes the display 102 to provide aninteractive virtual environment 104 to a user. The processing unit 101,output devices 102, and the input devices 103 may be provided in anysuitable arrangement as long as the elements of the disclosure areimplemented therein in order to provide the interactive virtualenvironment 104 to a user communicating with the system through a userinterface, e.g. in a standalone computer, in a single housing, such as amobile phone, tablet computer or other mobile device, in separatehousings such as in a desktop computer setup, and/or in a distributedset-up, at different locations, such as by accessing networked computingresources. The processing unit 101 may thus comprise, or have access to,computing resources to retrieve programmed instructions, virtual toyconstruction library data, virtual environment data, and/or to make useof processing power located remotely from a user interface provided bythe display and/or input devices, in order to provide the interactivevirtual environment 104 to the user. Suitable input and output devices102, 103 may include, but are not limited to, one or more of displaydevices, loudspeakers, sound and mechanical feedback generators, lightemitters, or the like, keyboard, mouse, touch sensitive pads, opticalsensors, computer vision devices, eye trackers, motion and gesturedetection devices, head-mounted devices, tactile interfaces, implantableinterfaces, and the like. Output devices 102 and input devices 103provide a user interface allowing the user to interact with the virtualenvironment 104 for building interactive virtual toy construction modelsand subsequently interactively playing with the constructed model. Thesystem 100 allows to not only build and inspect an appearance of avirtual model, but also to create an interactive model, explore itsfunctionality in an interactive virtual environment, and/orinteractively play with it. The user may also add further passive andinteractive models to construct an entire interactive virtual world.Building and playing interaction modes may even be combined in the sameuser session, thereby allowing for a playfully educational userexperience. According to a particularly advantageous embodiment thesystem may also be used as a game creation system, where a user maycreate interactive challenges and tasks for a player 99, which may beconstructed in the form of interactive virtual toy construction modelsplaced in one or more virtual world scenes, and which may be combined ina game for virtual game play.

The interactive virtual environment 104 has a coordinate system fordefining positions of virtual objects with respect to each other. Thecoordinate system may have a reference plane, such as a horizontalreference plane 110 with horizontal directions being oriented parallelto the horizontal reference plane 110 and vertical directions beingoriented perpendicular thereto. The virtual environment may comprisebackground elements 112, such as a landscape, vegetation, buildings,and/or any other objects defining a background topography of the virtualenvironment 104.

The virtual environment 104 provides virtual toy construction elements115, 116. All virtual toy construction elements 115, 116 may have ashape and coupling members as may be found in corresponding physical toyconstruction elements. The virtual toy construction elements 115, 116are thus configured for building a virtual toy construction model. Usingany suitable input method associated with the one or more input devices103 a user may instruct the system 100 to build any desired virtual toyconstruction model from the virtual toy construction elements 115, 116provided by the virtual environment 104. For example, a user may use oneor more input devices 103 of the system 100 to select and move virtualtoy construction elements 115, 116 so as to position them with respectto each other, and to engage their coupling mechanism, thereby defininga virtual toy construction model. Furthermore according to someembodiments, a user of the system 100 may import data definingpreviously constructed virtual toy construction models in terms of thevirtual toy construction elements 115, 116 included in the model, theirrelative position, and their connectivity with respect to each other.Examples of virtual toy construction models, which are all constructedfrom passive virtual toy construction elements 115 are seen in FIG. 5 asdecorative models 118 (pavilion, torches, animal), a tower 119 with atreasure chest on top, and a platform 120, all resting on the referencelevel 110 of the virtual environment 104 as here visualized by theshadows projected onto the reference plane 110.

A virtual toy construction model typically includes a plurality ofvirtual toy construction elements 115, 116, such as two or more virtualtoy construction elements, which are directly or indirectly connected toeach other. The connectivity is determined by the connection of thevirtual toy construction elements to each other through their respectivecoupling members. A direct connection may be established betweenadjacent virtual toy construction elements by engaging cooperatingcoupling members of the adjacent virtual toy construction elements toeach other. An indirect connection may be established between virtualtoy construction elements via directly connected intermediate virtualtoy construction elements in the same toy construction model. Virtualtoy construction elements in a virtual toy construction model may thusbe directly and indirectly connected to each other. The termconnectivity generally covers both direct connectivity by directconnections between adjacent virtual toy construction elements, andindirect connectivity by indirect connections via direct connections tointermediate virtual toy construction elements that are directlyconnected to each other. A virtual toy construction model may thus bedefined as a fully connected set of virtual toy construction elements,wherein connectivity of the virtual toy construction elements mayinclude direct and indirect connectivity. The term “connection” is hereunderstood as representing a mechanical coupling between virtual toyconstruction elements corresponding to the mechanical coupling ofphysical toy construction elements.

The virtual environment may further provide an avatar 99 of a playerallowing a user acting as a player to move around and to interact withthe virtual environment 104, and in particular with the interactive toyconstructions elements and models in the virtual environment 104. Theuser may control the avatar 99 using any suitable input methodassociated with the input devices 103.

The virtual toy construction elements 115, 116 may be grouped intodifferent sets according to their properties. A first set of virtual toyconstruction elements defines passive virtual toy construction elements115 corresponding in shape and coupling members to physical toyconstruction elements as already described above. The passive virtualtoy construction elements take up virtual space corresponding to theirpre-defined shape and size. The passive virtual toy constructionelements 115 do not provide any interactive functional behavior beyondthe coupling functionality representing the mechanical connection withother virtual toy construction elements 115, 116. The passive virtualtoy construction elements 115 thus allow for building passive virtualmodels, such as the passive models 118, 119, 120 shown in FIG. 5 , whichmay be placed in the virtual environment, and which may be gazed at andinspected by moving around in the virtual world, e.g. from a point ofview following an avatar 99 controlled by the user. A second set ofvirtual toy construction elements defines interactive virtual toyconstruction elements 116. Just like the passive virtual toyconstruction elements 115, the interactive virtual toy constructionelements 116 are configured for being connected to other virtual toyconstruction elements 115, 116 for building a virtual toy constructionmodel. However, the interactive virtual toy construction elements 116are further configured to provide interactive functionality beyond themere coupling mechanics of passive virtual toy construction elements115. As further detailed below, the interactive functional behavior ofan interactive virtual toy construction element 116 may be imparted toall virtual toy construction elements that are directly or indirectlyconnected to it.

The interactive functional behavior of an interactive virtual toyconstruction element 116 may thus be applied to an entire model to whichit is connected. Thereby, a user of the system may create a virtualinteractive object as a virtual toy construction model with aninteractive behavior as determined by the functional behavior of theinteractive virtual toy construction element included 116 in the model.The interactive virtual toy construction elements 116 are therefore inthe following interchangeably also referred to as behavior toyconstruction elements, and in so far the toy construction elements referto brick shaped toy construction elements, they may also be referred toas behavior bricks. However, the disclosure is not limited to brickshaped toy construction elements, as long as the virtual toyconstruction elements are adapted for being connected to each other in amodular manner for modular model building.

Advantageously, each of the virtual interactive virtual toy constructionelements 116 may be configured to have a specific interactive behaviorassociated with it. Furthermore, multiple interactive virtual toyconstruction elements 116 may be connected so as to construct a combinedinteractive behavior based on a combination of their respectiveinteractive behaviors. Thereby, a complex interactive behavior can beconstructed from a combination of simple functional elements of multipleinteractive virtual toy construction elements 116 in an easy andparticularly intuitive manner. Consequently, a modular system forbuilding virtual objects with complex interactive behavior is obtainedthat reflects the simplicity and intuitive modular building process ofphysical model building with physical toy construction elements. Thecombination may include a superposition of respective functionalities ofthe interactive virtual toy construction elements 116 that are combined,such as a superposition of two different motion patterns. Alternativelyor in addition thereto, the combination may include linking elements ofthe interactive behavior logically together, e.g. to build a logicalsequence of interactive behavior, such as a trigger condition activatinga motion pattern. The combination may be created by directly connectingthe interactive virtual toy construction elements 116 to each other, orindirectly connecting the interactive virtual toy construction elements116 to each other, e.g. via a path of intermediate passive virtual toyconstruction elements that are directly connected to each other. As alsofurther detailed below, the combined interactive behavior may beimparted to all virtual toy construction elements 115, 116 according totheir connectivity. Advantageously, the combined functional behavior maythus be applied to an entire model constructed from passive andinteractive virtual toy construction elements 115, 116 that areconnected to each other. Thereby, a user of the system may easily createa virtual interactive object as a virtual toy construction model with acomplex interactive behavior as determined by the combined functionalityof multiple interactive virtual toy construction elements 116 includedin the model.

The interactive behavior of an interactive virtual object, such as aninteractive toy construction element or model, is activated by astimulus received at a stimulus input of the interactive virtual object.The received stimulus may activate a response function producing aresponse at a response output of the interactive virtual object. Thestimulus may be derived from an activating event, such as entering aparticular operational mode, e.g. a switching to a play mode of thesystem, or entering a testing function within a building mode of thesystem. The stimulus may also be derived from a response output providedby one or more other interactive virtual construction elements. Forexample a response output of a first interactive virtual toyconstruction element may be linked to the stimulus input of a secondinteractive virtual toy construction element, wherein the secondinteractive virtual toy construction element is configured to activateits response output in response to receiving at its stimulus input apre-determined response output state from the first interactive virtualtoy construction element. The stimulus required for activating aresponse may be pre-defined, e.g. the response may be activated bydefault upon entering a certain operational mode. such as upon enteringa playing mode or a testing mode. Alternatively or in addition thereto,the stimulus required for activating a response may be configurable,such as user-configurable, e.g. in a building mode. Configuring theactivation mechanism of an interactive virtual toy construction elementmay include selecting one or more activation conditions, settingthreshold values or parameter ranges for activation, selectingactivation input from specific sources, and setting and/or selecting oneor more activation conditions that may be required to be fulfilled oneat a time (e.g. multiple conditions grouped in a logical “OR” list) orin combination (e.g. multiple conditions grouped in a logical “AND”list). The system may further include user interface elements thatfacilitate prompting for and receiving configuration input from a user.

The term “link” as used herein is understood as a functional associationbetween interactive virtual toy construction elements. An example of asimple link may be a trigger linked to an action, wherein activation ofthe trigger causes activation of the action. A link between interactivevirtual toy construction elements may be configured independent ofconnectivity. An example for a link that is independent of connectivitymay be a remote trigger attached to a first model, where a responseoutput of the trigger is linked to the stimulus input of an actionconnected to a second model that is separate from the first model.However, connectivity may also be used as a parameter for defining orconfiguring specific links (e.g. “all connected”, “directly connected”,“indirectly connected”). For example, an interactive virtual toyconstruction model may, besides a number of passive virtual toyconstruction elements, also include interactive virtual toy constructionelements for implementing a rotation action, a sound action, and aproximity trigger, which is activated when an activating object isdetected within a distance range from the proximity trigger, and whereinthe proximity trigger is only directly connected to the sound action. Bydefining a link only between the proximity trigger and the sound action,e.g. based on the direct connection between the two, the generation ofsound output from the interactive model may be configured to only occurwhen the activating object approaches the interactive model, whereas therotation movement of the model may be activated independent of theproximity trigger, e.g. upon entering a play state, so as to cause theinteractive model to rotate continuously.

Advantageously according to some embodiments, the system 100 maycomprise a building mode for constructing interactive virtual toyconstruction models from passive and interactive virtual toyconstruction elements 115, 116. The building mode may further provideconfiguration elements and/or indicators on the user interface, whichare adapted for configuring the interactive virtual toy constructionelements. The building mode may further provide testing componentsthrough the user interface, which are adapted for testing the functionalbehavior of interactive virtual toy construction elements, theirconfiguration, and of the models constructed from these elements.Further advantageously, the system may be configured for multiple usersto join the same virtual environment for building virtual toyconstruction models together, and/or together create a video game byconstructing interactive challenges and tasks in the form of interactivevirtual toy construction models placed in one or more virtual worldscenes. The one or more users may then play with the one or moreinteractive models or game, and/or share the interactive one or moremodels or game, e.g. through networked services, for other users to playwith the interactive virtual toy construction models or games.

Advantageously according to some embodiments, the system may furthercomprise a playing mode for playing with the interactive virtual toyconstruction models constructed from passive and interactive virtual toyconstruction elements 115, 116. According to a particularly advantageousembodiment, the playing mode may allow a user to play a video game thathas been created using the system. Further advantageously, the playingmode may be configured to allow multiple users to join the video gamethat has been created using the system and play the video game together.

Reference is now made to FIGS. 6 and 7 showing examples of interactivevirtual toy construction elements 116, which are grouped into so-calledactions 600 and triggers 700. The actions 600 comprise interactivevirtual toy construction elements 6 xx implementing an action behavior,called action bricks: responsive to receiving a stimulus at a stimulusinput, the action bricks activate an action response at the responseoutput, such as motion, sound, and/or visual effects. By connecting anaction brick 6 xx to a virtual toy construction model the correspondingaction behavior may be applied to the entire model.

The triggers 700 comprise interactive virtual toy construction elements7 xx, called trigger bricks implementing a trigger behavior: responsiveto receiving a stimulus at the stimulus input, the trigger bricksactivate a trigger response at the response output. By connecting atrigger brick 7 xx to a virtual toy construction model the correspondingtrigger behavior may be applied to the entire model.

A trigger brick 7 xx may be linked as an activation trigger to thestimulus input of one or more other interactive virtual toy constructionelements. Activation of the trigger brick may thus be used to causeactivation of the interactive behavior of the one or more interactivevirtual toy construction elements to which it is linked, subject tofulfilling a trigger condition of the trigger brick. As also mentionedabove, in some embodiments, linking the response output of oneinteractive toy construction element to the stimulus input of one ormore other interactive toy construction elements may be independent ofconnectivity. Thereby the interactive behavior of a first interactivetoy construction model may be linked to the interactive behavior of asecond interactive toy construction model that is separate from thefirst interactive toy construction model. For example, a triggerbehavior applied to a first model may be linked to activate an explosionbehavior applied to a second model that is located remote from the firstmodel in the virtual environment. The first model may then be used as aremote trigger for exploding the second model.

By way of example, a set of behavior bricks including action bricks 6 xxand trigger bricks 7 xx will now be described in more detail. However,the skilled person will understand that numerous other interactions maybe implemented and the conceivable actions and triggers that may beimplemented by interactive virtual toy construction elements are notlimited to the activation input, action and trigger output, and/orconfiguration options mentioned here. Also, while a single specificrepresentation of a virtual toy construction element is chosen as acarrier for the interactive functionalities implemented therein, anyform and shape of a virtual toy construction element may be used as acarrier for the interactive functionality, as long as the form and shapeof the virtual toy construction element is compatible with the othervirtual toy construction elements of the virtual toy construction systemfor the purpose of connecting the virtual toy construction elements toeach other and building virtual toy construction models.

The set of actions 600 as shown in FIG. 6 may include multiple actionbricks 611, 612, 613, 621, 622, 623, 631, 632, 633, 641, 642, 643, 651,652, 653, each action brick implementing a different respective actionresponse, which may be activated in response to any suitable activationevent registered at the stimulus input of the action brick. An actionresponse may be provided as user-perceptible output at the userinterface of the system, through any one or more of the output devices102.

Animation brick 611 may implement movements and sound output mimickingactivity of an animate being, which may be pre-configured and/oruser-configurable to represent a pet, a cartoon character, a wildanimal, a monster, a ghost, an alien, a robot, or the like.

Sound brick 612 may implement sound output, which may be configured toselect or generate a specific audio sequence, such as speech, ambientsounds, music, context specific sounds, in response to an activatingstimulus.

Control brick 613 may implement a motion control output, in directresponse to operation of control elements of one or more input devices103 at the user interface, such as keyboard input, joystick input, gamecontroller input, visually detected and/or touch-based gesture input,acceleration and/or gyroscopic sensor readings. By connecting a controlbrick to a virtual toy construction model, the model can be converted tobehave as a player's avatar, which moves around the virtual environmentin response to control input from a user operating corresponding playercontrol elements of the system.

Elevator brick 621 may implement vertical up and down movement output inresponse to an activating stimulus, which may be configured, e.g. withrespect to the number of consecutive up and/or down movements, theelevation height of the movement, speed, acceleration, or similarparameters.

Explosion brick 622 may implement an explosion action in response toreceiving a trigger stimulus. The explosion action may be configured,e.g. with respect to the strength of the explosion blast.

Hazard brick 623 may implement a weakening, toxic, or even killingeffect affecting one or more of the players or animate beings in thevirtual environment, typically in response to a trigger condition input.Configuration may determine the level and/or duration of the hazardaffecting the player, a range of the hazardous effect, whether or towhich extend the hazardous effect may be screened and/or healed,consumption or not of the hazardous effect, etc.

Hovering brick 631 may implement a hovering movement output, which maybe configured, e.g. with respect to the hovering height, and anamplitude of an optional oscillatory up-and-down bopping movement or anyhorizontal movements superimposed to the hovering movement, resilienceof the hovering force with respect to simulated vertical forces, etc.

Tracking brick 632 may implement a tracking motion output, which may beconfigured, e.g. to track a specified object, which may be configured,e.g. with respect to the type of tracking motion performed, and/or withrespect to delay, speed and/or acceleration of the tracking response tomimic a desired tracking behavior. For example, the tracking motion maybe a rotational motion around a vertical axis for orientation of theinteractive object along a line of sight to a target object, such as aplayer's avatar. In another example, the tracking behavior may include afollowing motion, where the interactive object not only is oriented, butalso moves towards the specified target object. Parameters for thedelay, speed and/or acceleration of the response may configure themotion for mimicking inertia in the tracking behavior, where a slowerresponse makes it easier for the targeted object to dodge and escape thetracking, whereas a faster response makes it more difficult.

Game lost brick 633 may implement an end-of-game state output in avirtual game environment where a player loses the game, in response todetecting fulfilment of a “LOOSE” condition at the stimulus input.

Transport brick 641 may implement a horizontal movement along adirection as indicated by an arrow on the side of the brick, which maybe configured, e.g. with respect to length of travel, and speed and/oracceleration of the movement.

Pick-up brick 642 may implement the possibility for a player to pick upgame assets in a game, in response to an activating stimulus. Thepick-up brick may be configured, e.g. with respect to the type of assetmade available, the amount of asset gained (or lost) by the pick-up,etc.

To-and-fro brick 643 may implement an oscillatory horizontal to-and-fromovement, which may be configured, e.g. with respect to the length ofthe to-and-fro movement, speed and/or acceleration, phase angle of theoscillation, etc.

Rotation brick 651 may implement a rotational movement around apre-determined axis of rotation, such as a vertical axis of rotation,which may be configurable, e.g. with respect to angular speed and/oracceleration, and with respect to orientation and location of the axisof rotation with respect to a reference point in or on the rotationbrick 651. For example, the axis of rotation may be pre-configured topass through the center of the brick. Furthermore, the rotation may bepre-configured to occur around a vertical axis, wherein a positive valuefor the angular speed may denote rotation in a first direction (e.g.“clockwise”), and a negative value for the angular speed may denoterotation in a second direction opposite to the first direction (e.g.“anticlockwise”).

Gun brick 652 may implement a shooting output, which may beconfigurable, e.g. with respect to the type of projectile or beamemitted by the gun, with respect to range and repetition of the shootingaction, and/or with respect to the damage inflicted on the target by ahit.

Game won brick 653 may implement an end-of-game state output in avirtual game environment where a player wins the game, in response todetecting fulfilment of a “WIN” condition at the stimulus input.

The set of triggers 700 as shown in FIG. 7 may include multiple triggerbricks 711, 712, 721, 722, 731, 732, each trigger brick implementing adifferent respective trigger output, which may be activated in responseto any suitable activation event registered at the stimulus input of thetrigger brick.

Button brick 711 may implement a trigger state output in response to aswitching condition registered at the stimulus input, which may beconfigurable e.g. with respect to the type and duration of the switchingfunction and trigger state output, such as flipping between an on andoff state, switching a trigger output state from a normally off state toa temporary on state, switching a trigger output state from a normallyon state to a temporary off state, duration of providing the triggerstate output, dialing through a list of more than two trigger states, anumber of trigger states selectable by consecutive activation of theswitch, etc.

Proximity brick 712 may implement a trigger output to occur as soon asan activating object, such as a player's avatar, is in proximity of anobject to which the proximity trigger behavior is applied, whereinproximity may be determined according to a distance of the activatingobject from a reference point of the proximity brick. The proximitybrick may be configurable, e.g. with respect to the object or objectsthat may activate the trigger behavior, or with respect to the range ofdistances between the activating object and the proximity brick thatcause activation of the trigger state output.

Pick-up trigger brick 721 may implement generation of a trigger outputactivated by registering one or more pick-up actions occurring elsewherein the virtual environment, which may be configurable with respect tothe pick-up actions required to activate the trigger output, such aswhich or how many of one or more available pick-up actions need to beperformed by a player's avatar in order to activate the trigger output.

Random number brick 722 may implement the generation of a random numberoutput, in response to receiving an activating stimulus at the stimulusinput. The random number brick may be configurable, e.g. with respect tothe type and range of the number output, or even with respect to therandom number generation algorithm used.

Timer brick 731 may implement a trigger output with a time delay thatstarts running upon activation of the timer brick, which may beconfigurable, e.g. with respect to the duration of the time delay.

Touch brick 732 may implement a trigger output to occur as soon as aplayer avatar touches an object to which the touch trigger behavior isapplied, which may be configurable, e.g. with respect to a minimumduration of touch activation required before the trigger output isgenerated.

EXAMPLES

Turning to FIGS. 8 and 9 , an example of building and playing with aninteractive toy construction model using an embodiment of a systemaccording to the disclosure, such as a system as shown in FIG. 5 , isnow described. The system is configured to provide a virtual environment104 in a first operational mode, in the following referred to asbuilding mode, which is mainly adapted for building and configurationoperations to be performed by a user. FIG. 8 shows the system in thebuilding mode, wherein insert (b) shows an enlarged view of a centralportion of the view (a) of the virtual environment 104 as marked by thebroken line frame. A player's avatar 99 may be used as a reference markfor a point of view for presenting a scene of the virtual environment tothe user. The avatar may be configured to merely watch the buildingoperations when the system is in the building mode. Alternatively, theavatar may be configured to participate in the building operations inorder to enhance the interactive experience. The system is furtherconfigured to provide the virtual environment 104 in a secondoperational mode, in the following referred to as playing mode, which ismainly adapted for a user to playfully interact with the virtualenvironment, e.g. by means of a player's avatar 99. FIG. 9 shows thesystem in the playing mode, wherein insert (b) in FIG. 9 shows anenlarged view of a central portion of the view (a) of the virtualenvironment 104 as marked by the broken line frame.

The virtual environment 104 has a horizontal reference plane 110 whereinhorizontal directions are parallel to the reference plane 110, andvertical directions are perpendicular to the reference plane 110. Thevirtual environment may further provide a background landscape, defininga topography of the virtual environment 104. The virtual environment 104comprises virtual toy construction elements 115, 116, here shown asbrick shaped virtual toy construction elements 115, 116. Each of thesevirtual bricks 115, 116 have stud and cavity type coupling elements forconnecting the virtual bricks 115, 116 to each other. The virtual bricks115, 116 include a set of passive virtual bricks 115 and a set ofinteractive behavior bricks 116 with functionalities as alreadydescribed above. The set of behavior bricks 116 may comprise any of theaction bricks 6 xx and trigger bricks 7 xx with functionalities as alsodescribed above. The virtual environment 104 may further comprisevirtual toy construction models 118, 119, 120 previously constructedfrom passive bricks 115, such as decorative models 118, a tower with atreasure chest 119, and a platform 120.

The enlarged inset (b) in FIG. 8 shows the construction of aninteractive virtual toy construction model 836 from a combination ofpassive and interactive bricks 115, 116 connected to each other. Theinteractive virtual toy construction model 836 comprises a passiveplate-shaped brick 115 resting on the reference level 110, and anelevator brick 621. Elevator brick 621 has a vertical movementfunctionality as described above with reference to FIG. 6 , wherein thevertical movement output is configured to be activated by default assoon as the system enters playing mode. Elevator brick 621 is connectedto a top side of the plate-shaped brick 115 by means of cooperatingcoupling elements. By connecting the behavior brick 621 to the passiveplate-shaped brick 115, the functionality of the behavior brick isimparted to the passive plate-shaped brick 115, thereby turning theentire virtual toy construction model 836 into an interactive virtualtoy construction model exhibiting the interactive behavior as defined byand configured in the behavior brick 621. Upon entering the playing modethe action response is activated as indicated by the block arrow in FIG.9 . As best seen in insert (b) of FIG. 9 , the entire interactivevirtual toy construction model 836 starts moving upward in a verticaldirection as indicated by the block arrow and the shadow 836 a of themodel 836 projected onto the reference plane 110. In the example ofFIGS. 8 and 9 the avatar 99 merely observes the scene, but does notdirectly interfere with the interactive object 836 thus created.

FIGS. 10-12 show a further example of modifying an interaction behaviorof a virtual toy construction model, wherein FIGS. 10 and 12 show thebehavior of the virtual toy construction model when the system is in aplaying mode before and after the modification, respectively, andwherein FIG. 11 shows applying the modification to the virtual toyconstruction model when the system is in a building mode. The scene viewseen in FIG. 10 shows the same virtual environment 104 as alreadydiscussed above with respect to FIGS. 5, 8, and 9 with a backgroundlandscape, decorative models 118, a tower 119 with a treasure chest ontop, and a platform 120. All models are created from passive virtual toyconstruction elements 115, such as the plate-shaped brick also seen inthe scene view of FIG. 10 . The scene is viewed from the point of viewof a third person following the player's avatar 99, which in this scenehas jumped onto the platform, contacting the top thereof. However, sincethe platform is constructed from passive bricks 115, no interactivebehavior is associated with the platform 120. FIG. 11 shows the virtualenvironment 104 in a building mode with a background landscape, passivebricks 115, interactive behavior bricks 116, and virtual toyconstruction models as already described above with respect to FIG. 8above. The view (a) of FIG. 11 shows the scene in an overviewperspective following behind the avatar 99, wherein insert (b) in FIG.11 shows an enlarged view of a central portion of the view (a) of FIG.11 as indicated by the broken line frame. The scene of FIG. 11 furthercomprises an interactive toy construction model 1001, which has beenconstructed by connecting a combination of interactive behavior bricks116 to the passive toy construction model 120 resting on the referenceplane 110 of the virtual environment 104. More particularly, the passiveplatform model 120 has been modified by connecting an elevator brick 621directly to the top of the platform model 120. However, in contrast tothe model 836 of FIGS. 8 and 9 , the elevator action is now activatedsubject to fulfilment of an activation condition in the form of a touchtrigger brick 732 connected to the top of the elevator brick 621. Byconnecting the touch trigger brick 732 to the top of the elevator brick621, the touch trigger brick 732 is also indirectly connected to theplatform model 120 via the intermediate of the elevator brick 621.

By connecting the elevator brick 621 to the platform model 120, theelevator behavior may be imparted to all virtual toy construction bricksof the platform model 120. Furthermore, since the touch trigger brick732 is also connected to the elevator brick, the touch trigger brick 732also inherits the elevator behavior. By connecting the touch triggerbrick 732 via the elevator brick 621 to the platform, the touch triggerbehavior may also be imparted to the elevator brick and to all virtualtoy construction bricks of the platform model 120. Thereby aninteractive virtual toy construction model 1001 of an elevator platformis constructed. Upon activation of the action response, the elevatorplatform model 1001 performs a vertical movement as defined by andconfigured in the elevator brick 621, wherein the vertical movementaction may be triggered in response to a player's avatar 99 touching theelevator model 1001. The interactive behavior of the modified platformis best seen in FIG. 12 showing the scene in playing mode in a similarview as in FIG. 10 , and where the avatar 99 has been controlled to jumponto the platform 120 contacting the top thereof. While the platform 120in FIG. 10 does not change position, the modified elevator platform 1001now detects the avatar touching the top of the platform as indicated inFIG. 12 by the star labelled “TRIGGER”. The trigger behavior as definedby and configured in the touch trigger brick 732 is linked to thevertical movement behavior as defined by and configured in the elevatorbrick 621. More specifically, the trigger response of the touch triggerbrick 732 may be provided as an activating stimulus to the elevatorbrick 621. As a consequence, the detected TRIGGER event activates thevertical movement behavior of the interactive elevator platform model1001, and the elevator model 1001 starts moving vertically upward awayfrom the reference plane 110, thereby carrying the avatar 99 to the topof the tower 119 as evident from the relative position of the elevatormodel 1001 and the avatar 99 with respect to the treasure chest on topof the tower 119. Conceivably, also the treasure chest can be convertedinto an interactive item, e.g. by placing a pickup action brick 642inside the treasure chest, which may be configured to be activated assoon as the avatar 99 reaches the treasure chest by means of the flyingelevator platform 1001. Thereby, a modular system for constructingarbitrary interactive worlds in an intuitive and easy manner isachieved.

Advantageously, the system may be used by a user, e.g. in a buildingmode, to create an interactive video game. The system may then be usedby the user, e.g. in a playing mode, to play the interactive video game.Further advantageously, a user may also share the created game for otherusers to play the interactive video game. Advantageously according tosome embodiments, the system may be adapted to provide the virtualenvironment 104 as a multiple user environment, wherein multiple users,each user being represented by a respective player's avatar 99, may jointhe same virtual environment 104 in the building mode to collaborate inbuilding and configuration operations. Furthermore, the system may alsobe adapted to provide the virtual environment 104 as a multiple userenvironment allowing multiple users to join as players in the playingmode to playfully interact with the virtual environment 104 and otherplayers. In some embodiments, the virtual environment 104 may beimplemented on the basis of a game engine software, such as the Unitygame engine available through Unity Software Inc., San Francisco, USA.

What is claimed is: 1-21. (canceled)
 22. A system for constructinginteracting virtual objects comprising: a user input device; and aprocessing unit configured to: provide an interactive virtualenvironment to a user based on programmed instructions, virtual toyconstruction library data, or virtual environment data, the interactivevirtual environment defining virtual toy construction elementsconfigured for building virtual toy construction models; receive asignal for the input device by a user; build, via a building mode, avirtual toy construction model from the virtual toy constructionelements provided by the virtual environment based on the signalreceived by the input device, the virtual toy construction modelconfigured to provide interactive functionality determined by afunctional behavior of the virtual toy construction model, wherein: thevirtual toy construction elements are configured to have a specificinteractive behavior associated therewith, the functional behavior ofthe virtual toy construction model activated by a stimulus received at astimulus input of the virtual toy construction model, the receivedstimulus activating a response function producing a response at aresponse output of the virtual toy construction model, the stimulusderived from an activating event, such as entering a particularoperational mode, or entering a testing function within a building modeof the system, or from a response output provided by the virtual toyconstruction elements, the building mode provides configuration elementsand indicators on a user interface adapted for configuring the virtualtoy construction elements, testing components adapted for testing thefunctional behavior of virtual toy construction elements, the system isconfigured for multiple users to join the same virtual environment forbuilding virtual toy construction models together, the system alsoincludes a playing mode separate from the building mode configured forplaying with the virtual toy construction model constructed from thevirtual toy construction elements, the playing mode allowing a user toplay a video game that has been created using the system, the virtualtoy construction elements including action virtual toy constructionelements, the action virtual toy construction elements, responsive toreceiving, the stimulus at the stimulus input, activating an actionresponse at the response output such as a motion, sound, and/or virtualeffects, the action virtual toy construction elements selected from thegroup consisting of: an animation brick, sound brick, control brick,elevator brick, explosion brick, hazard brick, hovering brick, trackingbrick, game lost brick, transport brick, to-and-fro brick, rotationbrick, gun brick, and game won brick, the virtual toy constructionelements including trigger virtual toy construction elements, thetrigger virtual toy construction elements, responsive to receiving thestimulus at the stimulus input, activating a trigger response at theresponse output, the trigger virtual toy construction elements selectedfrom the group consisting of: a button brick, proximity brick, pick-uptrigger brick, random number brick, timer brick, and touch brick. 23.The system of claim 22, wherein the interactive virtual environmentincludes a coordinate system for defining positions of virtual objects,the coordinate system having a reference plane.
 24. A system firconstructing interacting virtual objects comprising: a user inputdevice; and a processing unit configured to: provide an interactivevirtual environment to a user based on programmed instructions, virtualtoy construction library data, or virtual environment data, theinteractive virtual environment defining virtual toy constructionelements configured for building virtual toy construction models;receive a signal for the input device by a user; build, a virtual toyconstruction model from the virtual toy construction elements providedby the virtual environment based on the signal received by the inputdevice.